DE1046678B - Frequency divider with monostable multivibrator - Google Patents

Description

Various frequency divider circuits have hitherto become known for dividing a pulse train in a specific division ratio. In principle, these circuits can be divided into two large groups. One group of frequency-independent dividers produces a division in the ratio of 2: 1 per divider stage. These divider circuits are mostly designed as bistable multivibrators «! educated. They are particularly preferred in counting circuits. Such frequency-independent divider stages have the advantage of great stability. A disadvantage here, however, that each stage binary only, so * 2: 1, is divided and therefore larger, 2 "corresponding divider ratios η stages must be connected in series addition, there is the further disadvantage that with an odd number, and the second" additional different ratio Tube stages for resetting become necessary.

Larger divider ratios in one stage can be achieved with the second group of divider circuits, with the so-called frequency-dependent dividers. So far, many have been free for this purpose vibrating blocking oscillators or multivibrators are used. However, these known arrangements have the big disadvantage of being quite unstable. Use brings somewhat more stable conditions of monostable multivibrators.

The known divider circuits, however, still have disadvantages, which include the fact that their natural frequency is not very stable and is strongly influenced by aging of the tubes used, by operating voltage fluctuations, etc. Another disadvantage is the shape of the lattice stress increase, which follows an r-function. As a result, especially in the case of large division ratios, there is a risk of triggering by the (n- 1) th pulse. Another disadvantage of the known circuits is the dependence on the shape and the amplitude of the trigger pulses.

A circuit arrangement is known in which the cathode current or the cathode voltage of the first tube, which carries a relatively high DC voltage on the grid, is stabilized with the aid of a cathode resistor and an additional diode. The effort required for this is relatively great, since two operating voltage sources must be present in addition to the additional diode. In another known circuit arrangement, only one operating voltage source is required, but here the grid can no longer be used for control purposes. Therefore the trigger pulse has to be applied to the anode. Fluctuations in the amplitude of the trigger pulses are extremely disruptive. It is frequency divider with monostable
Multivibrator

Applicant:

Max Grundig,

Fürth (Bay.), Kurgartenstrasse 37

Erich Schurig, Nuremberg,
has been named as the inventor

It is therefore necessary to connect a third tube in grid-base circuit as an impedance converter upstream of the divider stage. Here, too, the effort is relatively high, while the effect achieved is low. In both In some cases, the specified measures only serve to stabilize the period of oscillation. The present Invention has set itself the task of a frequency-dependent pulse frequency divider create, which avoids the disadvantages of the previously known frequency dividers of this type with simple means. Compared to the known circuits, which only stabilize the period of oscillation, the invention brings Significant progress, as purely technical circuit measures without additional switching elements not only the period of oscillation, but also the form of oscillation is stabilized and in addition, the other disadvantages of the known circuits are overcome.

According to the invention, with a frequency-dependent divider, which consists of two as a monostable multivibrator switched tubes, the division ratio being determined by the appropriate dimensioning of the frequency-determining i? C element is adjustable, especially for a large division ratio, from the anode A negative feedback branch is provided from the first tube to the control grid of this tube. In this branch at least one adjustable resistor is arranged. This resistance also causes the appropriate one Bias of the control grid and determined in connection with the coupling capacitance between the The anode of the second tube and the control grid of the first tube the frequency of the divider stage. The inventive Circuit has compared to the frequency-independent, binary divider circuits

809 699/239

Advantage of great simplicity. Relatively large division ratios can also be achieved with a stage consisting of only two tubes. This has the advantage of saving a great deal of tubes and switching elements. Compared to the known frequency-dependent divider circuits, there is a significant increase in stability. The stability is secured in several ways. On the one hand, the arrangement according to the invention is significantly more stable with respect to pulse amplitude fluctuations. This advantage arises as a result of a further advantage of the arrangement according to the invention. The fact that the frequency-determining resistor is connected to the anode results in a linearization of the grid voltage increase. In the known circuits in which the grid voltage of the first tube is achieved by a voltage divider between grid and supply voltage source or ground, the grid voltage increases according to an exponential function, as already noted. The resulting risk that the (n- l) th pulse causes the arrangement to tilt and therefore the divider ratio is changed, is substantially reduced in the divider according to the invention by the linearization of this increase. As a result, there is no risk of premature tipping even if the amplitude of the pulse fluctuates. As a result of the negative feedback according to the invention, the circuit arrangement is also more stable with regard to aging phenomena in the tubes, which preferably have an effect in changes in the slope. On the other hand, however, these changes in slope can also be caused by fluctuations in the operating voltages. In this case too, the circuit arrangement according to the invention has a stabilizing effect. It is therefore no longer necessary to stabilize the supply voltage separately. Due to the resistor provided in the negative feedback branch, the operating point of the tube is shifted accordingly when the slope changes, regardless of the respective cause of this change, and the necessary grid bias is changed to the same extent. Even in a connected circuit, fluctuations in the operating voltage and associated changes in the pulse amplitudes also change the voltage ratios of the divider stage, so that the ratio of the pulse amplitudes to the grid bias remains the same.

Further details and further advantages of the invention will be based on the drawing, which a Illustrates embodiment, explained in more detail. In the drawing there is a frequency-dependent one consisting of two stages Voltage divider shown. Both stages are constructed in the same way, so that in of the description only the first stage needs to be explained in more detail. The pulse train to be divided becomes The control grid 2 of the first tube 3 is supplied via a capacitor 1. From the anode 4 one leads Connection to the grid 5 of the tube 6. The tubes 3 and 6 are via a common cathode resistor 12 coupled. It is of course possible to use the two tubes 3 and 6 in a double system tube to unite. In the connection between the anode 4 and the grid 5 there is a resistor in a known manner 7 and, in parallel, a small capacitance 8 is provided. The capacity 8 is used to compensate the grid-cathode capacitance of the tube 6. From the anode 9 of the tube 6, a coupling branch leads Contains capacitor 10, to the grid 2 of the tube 3. The resistor 11 serves as a grid lead resistor for the tube 6. The supply of the operating voltage takes place in a known manner. From the anode 4 of the Tube 3 leads a negative feedback path 13 back to grid 2. This contains the two resistors 14 resp. 15, at least one of which is adjustable. The capacitance causes 10 in connection with the resistor 14 or 15 the setting of the tilt frequency of the monostable multivibrator. Of the frequency-determining resistor 15 was connected to ground in previously known circuits. This is the tube 3 is blocked in the initial state, and positive pulses must be applied to initiate the tilting process the grid 2 are fed. If only negative pulses are available, the resistance can 15 can also be connected to the operating voltage source of the two tubes. Then the tube 3 is in the initial state conductive and is blocked by negative impulses. According to the invention, the resistor is 15 not to the supply voltage source, but directly to the anode 4. This results in the aforementioned Stability of the circuit against changes in the slope of the tubes. Since both resistors 14 and 15 are very high resistance, so that there is practically only a DC voltage negative feedback, while the AC voltage does not reach the grid 2, since the two resistors 14 and 15 in connection with the grid-cathode path represent a very high-resistance voltage divider.

In the initial state, the tube 3 is open and carries electricity. When a negative impulse arrives, the tube 3 blocked, the voltage or current surge occurring at the anode 4 is the Grid 5 of the previously blocked tube 6 is supplied. This becomes conductive and charges the capacitor 10. This discharges after a time corresponding to the time constant via the grid 2 of the tube 3. This The grid therefore becomes more and more positive until the tube 3 takes over the line again and the tube 6 is blocked. The increase in the grid bias is completely linear, since the rise curve resulting from the discharge of the capacitor 10, which is normally a e-function would be sufficient, is linearized by the resistor 15. From work resistance 16 the Tube 6 is supplied with the correspondingly divided pulse train of the second stage.

If the output pulse of the first stage changes due to changes in the operating voltages has, the second stage remains stable, since the grid bias of the input grid of this Level was correspondingly reduced by the measure according to the invention and also a reduced one Impulse brings the second stage to tip over in the right proportion.

The invention can be used particularly advantageously in clock systems, in test image generators and the like. in which a large division ratio is to be achieved with little effort and great stability. she however, it is not limited to the exemplary embodiment shown and described. You can z. B. Also use with monostable univibrators (with variable pulse width) for stabilization.

Claims (1)

Claim: Frequency-dependent divider with two tubes connected as a monostable multivibrator, whereby the division ratio by appropriate dimensioning of the frequency-determining i? C element is adjustable, especially for large division ratios, characterized in that of the A negative feedback branch is provided and anode of the first tube to the control grid of this tube in this branch at least one adjustable resistor is arranged, which at the same time acts and in connection with the coupling capacitance between the anode of the second tube and the The control grid of the first tube determines the frequency of the divider stage. Considered publications: the appropriate pre-tensioning of the control grid can be found in RCA Review, September 1955, pp. 403 to 422. 1 sheet of drawings